Les activités de l'INTRIQ

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mai 13, 2020

When : Wednesday, May 13th, 2020

Where : Polytechnique Montréal

Organizers :
     Pr Denis Seletskiy, Polytechnique Montréal
     Pr Louis Salvail, Université de Montréal

mai 12, 2020

When : Tuesday, May 12th, 2020

Where : Polytechnique Montréal

Organizers : INTRIQ student committee

The event gives the opportunity for the INTRIQ community to collaborate and network with invited young researchers recently hired by private companies with activities in quantum information processing.

nov. 11, 2019

At Hotel Château Bromont

Organizers :
     Éva Dupont Ferrier, Université de Sherbrooke
     Dave Touchette, Université de Sherbrooke

90, rue Stanstead, Bromont QC J2L 1K6
Téléphone : 1 800 304 3433

Note : The INTRIQ Business meeting (reserved for members) will be held in room "Salle des cantons" on November 11th from 9h30 to 10h30

Meeting program

November 11th

10h30 - 10h55  Registration

10h55 - 11h00  Opening remarks (Salon A)

11h00 - 11h45  Pr Frédéric Dupuis, Université de Montréal
                         Purely quantum polar codes 

11h45 - 12h05  Marco David, Student, McGill University
                         QED. The Quest to Formally Verify Mathematics

12h05 - 13h30  Lunch  (Dining room - 4 Canards)

13h30 - 14h15  Dr Louis Gaudreau, National Research Council (NRC) - Ottawa
                         Entanglement distribution via coherent photon-to-spin conversion in semiconductor quantum dot circuits

14h15 - 14h45  Dr Joel Griesmar, Université de Sherbrooke
                         A mesoscopic spectrometer based on the Josephson effect

14h45 - 15h15  Coffee break  (Salon B)

15h15 - 15h45  Dr Stephane Virally, Polytechnique Montréal
                          Quantum optics in the time domain 

15h45 - 16h25  Industry & Startups in quantum technologies
                              Dr Félix Beaudoin, Les Technologies Nanoacademic Inc (www.nanoacademic.com)
                              Dr David  Roy-Guay, SB Quantum (www.sbquantum.com)
                              Pr David Poulin, Microsoft (0pen positions at Microsoft)

16h25 - 17h00  Equity, diversity & inclusion (minutes and photos of the workshop)

17h00 -             Poster session with refreshments (Salon B)

19h30 -             INTRIQ dinner (Knowlton room)

 

November 12th

  8h30 -  9h00  Pr Anne Broadbent, Université d'Ottawa
                          Quantum encryption with certified deletion

 9h00 - 10h00  Dr Tomas Jochym-O'Connor, IBM - Yorktown Heights, New York
                        Disjointness in stabilizer codes

10h00 - 10h30  Coffee break (Salon B)

10h30 - 11h30 Pr Signe Seidelin, Institut NEEL CNRS/UGA
                        Rare-Earth Doped Crystals for strain-coupled optomechanics

11h30 - 12h00  Dr Erika Janitz, McGill University
                         Cavity-Enhanced Photon Emission from a Single Germanium-Vacancy Center in a Diamond Membrane

12h00 - 13h30  Lunch  (Dining room - 4 Canards)

13h30 - 14h00  Pr Jérôme Bourassa, Cégep de Granby
                         Quantum illumination : exploiting quantum correlations when entanglement is lost

14h00 - 14h30  Dr Thomas Baker, Université de Sherbrooke
                          Modeling superconducting circuits with a tensor network

14h30 - 15h00  Dr Anirban Chowdhury, Université de Sherbrooke
                          Simulating thermal physics on quantum computers

15h00 - 15h30  Questions and answers

15h30 - 15h40  Closing remarks

 

Axes 1 - Software

(- Cette section est en anglais pour permettre aux specialistes non-fracophones de la lire -)

Information technologies are broadly divided into software and hardware. The hardware consists of the physical system that implements a given information-processing task, whereas the software consists in a set of instructions to be implemented by the physical system. Most software can in general be executed on diverse hardware and conversely hardware development is mostly independent of the software it will execute. Nevertheless, software and hardware developers must be in touch to understand each other's needs. In particular, software should take advantage of the hardware's features and circumvent its limitations, whereas hardware development is driven by its potential software applications. Quantum information technologies follow the same software/hardware paradigm: any future application will rely on both software and hardware solutions and it is imperative that they be designed hand in hand. INTRIQ's expertise is organized accordingly. This axis focuses on the software aspects.

Theme 1.1 - Quantum algorithms
Algorithms provide instructions that enable any information processor to accomplish its intended task; they are ubiquitous in technological devices. Likewise, algorithms will play an essential role in many areas of quantum information science, not limited to their use in future quantum computers. Shor's 1996 discovery of an efficient quantum algorithm to factor large numbers and hence break most encryption techniques currently used over the Internet is now widely known, but there exist many other quantum algorithms: website math.nist.gov/quantum/zoo/ presently mentions over fifty of them. Algorithms play other roles in quantum information science, ranging from testing new quantum error-correcting codes and simulating quantum hardware to optimizing quantum control. Techniques developed for one application can often serve other applications, so collaborations are paramount. To maximize medium-term impact, we shall concentrate on algorithms that can be implemented with very few qubits.

Theme 1.2 - Quantum communication and error correction
Our ability to communicate gigantic amounts of information reliably all over the globe is now commonly taken for granted. It turns out that communication and privacy can sometimes be greatly enhanced by exploiting quantum phenomena such as the possibility to send signals in superposition or to share entanglement. For instance, quantum cryptography is arguably the most advanced of all quantum information technologies, with devices being sold by several companies worldwide and dedicated satellites being planned and launched. Moreover, our ability to communicate reliably despite errors occurring in real-word devices hinges on error-correcting codes. Because quantum systems are particularly susceptible to noise, quantum error-correcting codes will likely be an integral part of all future quantum information technologies, not only for communication purposes. The launch by China in August 2016 of the first quantum communication satellite signalled the dawn of a new era for our discipline.

Theme 1.3 - Foundations of quantum theory
Quantum theory defies common sense as microscopic particles follow a different type of logic than what we are used to in our macroscopic experience. This theme aims at clarifying the conceptual foundations at the basis of quantum theory. Ultimately, our goal is to make sense of all its strangeness, such as its purported nonlocality, in disagreement with Feynman's famous aphorism: "I think it is safe to say that no one understands Quantum Mechanics". It was by thinking deeply about these issues that the founders of our field discovered potential applications that would open up the path to the technological revolution that we enjoy today. By clearly isolating and analysing the counterintuitive features that distinguish the quantum from the classical world, we can ask ourselves what use they could have that would outperform what can be achieved in the classical world. Thus, progress in understanding and interpreting quantum theory is at the root of novel applications of the theory.

 

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